English

Superfluid Density, Penetration Depth, Condensate Density

Superconductivity 2026-01-16 v1

Abstract

Fascination with the concept of superconducting (SC) {\it superfluid density} ρs\rho_s has persisted since the beginning of superconductivity theory, with numerical values of an actual density rarely provided. Over time ρs\rho_s, addressed mostly in cuprate and following high temperature superconductors, has become synonymous with the normalized (unitless) inverse square of the magnetic penetration depth λL\lambda_L (the London expression, with superfluid density denoted nsn_s), with interest primarily on its temperature TT dependence that is expected to reflect the T-dependence of the SC gap amplitude and gap symmetry. In conventional superconductors, generalized expressions from the London penetration depth via Ginzburg-Landau theory, then to BCS theory provide updated pictures of the supercurrent density-vector potential relationship. The BCS value λband\lambda_{band} is distinct from any particle density, instead involving particle availability at the Fermi surface and Fermi velocity as the determining factors, thus providing a basis for a more fundamental theory and understanding of what is being probed in penetration depth studies. The number density of superconducting electrons Ns(T{\cal N}_s(T=0) -- the scalar SC {\it condensate density} -- is provided, first from a phenomenological estimate but then supported by BCS theory. A straightforward relation connecting Ns(0){\cal N}_s(0) to the density of dynamically transporting carriers in the normal state at TcT_c is obtained. Numerical values of relevant material parameters including λband\lambda_{band} and Ns{\cal N}_s are provided for a few conventional SCs.

Keywords

Cite

@article{arxiv.2601.10578,
  title  = {Superfluid Density, Penetration Depth, Condensate Density},
  author = {Warren E. Pickett},
  journal= {arXiv preprint arXiv:2601.10578},
  year   = {2026}
}

Comments

11 pages

R2 v1 2026-07-01T09:06:14.176Z